Publication Date:
2024-05-27
Keywords:
Abrupt Climate Changes and Environmental Responses; Acaena/Polylepis; Acalypha; Accumulation model; ACER; Alchornea; Alnus; Amaranthaceae/Chenopodiaceae; Ambrosia-type; Anacardiaceae; Apiaceae; Artemisia-type; Asteraceae; Azolla; Bocconia; Borreria; Botrys; Brassicaceae; Calendar age; Calendar age, maximum/old; Calendar age, minimum/young; Caryophyllaceae; Cecropia; Classical age-modeling approach, CLAM (Blaauw, 2010); Counting, palynology; Croton; Cyathea-type; Cyperaceae; Daphnopsis; DEPTH, sediment/rock; Dodonaea; Drimys; Ericaceae; Eugenia; Fabaceae; Fuquene; Gaiadendron; Gunnera; Hedyosmum; Heliocarpus; Hydrocotyle; Hyeronima; Hymenophyllum/Phaeoceros/Selaginella-type; Hypericum; Ilex; Isoetes; Jamesonia; Juglans; Lamiaceae; Lemna; Liliopsida; Ludwigia; Lycopodium; Melastomataceae; Meliaceae; Miconia; Moraceae/Urticaceae; Myrica; Myriophyllum; Myrtaceae; Pilea; Plantago; Poaceae; Podocarpus; Polygalaceae; Polygonum; Polypodiales; Potamogetonaceae; Proteaceae; Quercus; Ranunculaceae; Rapanea; Rumex; Sample ID; Satureja-type; Solanaceae; Styloceras; Symplocos; Thalictrum; Type of age model; Typha; Vallea; Viburnum; Vismia; Weinmannia; Zea-type
Type:
Dataset
Format:
text/tab-separated-values, 8072 data points
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